Hinge clamp for a bicycle frame and other structures

ABSTRACT

A hinge clamp adapted to clamp a hinge assembly with an eyelet to position and protect a retraction spring, a counter-bore in the V-plate to accommodate the spring, and a finger loop to position the user&#39;s finger during operation. In some aspects the clamp may have a removable bolt-tightening handle, the release of which enables the handle to be removed to avoid damage and to prevent theft. The handle may be removable over the head of the bolt in a first rotary configuration, and be constrained under the head of the bolt in a second rotary configuration. A hinge clamp with a retained clamp plate that retains the position of the clamp plate near the handle when the hinge clamp is loosened.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a continuation in part of U.S. patent application Ser. No. 15/488,426 to Bianchi, filed Apr. 14, 2017, which claims priority to U.S. Provisional Patent Application No. 62/323,125 to Bianchi, filed Apr. 15, 2016, both of which are hereby incorporated by reference in their entirety.

BACKGROUND

Temporary structures that need to be erected and folded for transportation and storage are often held together with hinges secured by integrated clamps. These clamps are more effective if they can be tightened and released quickly, easily and safely, and if the parts are not easily broken or lost.

This relates specifically to hinge clamps of folding bicycles and the like, but may also apply to hinge clamps that secure other structures. It may also apply to other clamps and other such mechanisms that have cranks or handles that can be spun by using a human finger or similar object inserted into a hole as an axis for spinning a crank.

Manufacturers offer bicycle frames that fold by way of hinges secured by clamps: two flanges or leaves are held together on one side by a pin running along the edges, and on the other side by a “V”-shaped clamp block or plate. The opening of the “V” is situated facing the pin and driven against surfaces along the open edges of the hinge. These surfaces are angled to mate with the angle of the “V”. The “V” plate is wedged onto the edges of the hinge by tightening a bolt running through it. This bolt is affixed to one of the two leaves perpendicular to the axis around which the leaves rotate by means of a threaded bore. The bolt head is equipped with a winged member that acts as a wrench to be turned by hand, driving the parts firmly together. Friction keeps the structure together despite the jarring conditions of a bicycle ride. The inner surfaces of the “V” are relieved along the center to concentrate clamping force on the outer edges of the hinge to resist bending loads and to clear brazed fillets connecting the hinges to the tubing of the bicycle frame.

Disadvantages of this design are that the operation of opening and closing the mechanism is unnecessarily frustrating, as are other aspects of its service as described below.

The clamp plate may rotate into the path of the closing hinge, preventing closure. The plate is not automatically retracted when released, and may prevent opening even when unbolted. The travel of the bolt away from the hinge is not limited, so time may be wasted turning the bolt unnecessarily. In transit, the bolt is unconstrained by friction, so vibration can work the bolt out of its bore, subjecting it to deformation or loss. The wing bolt requires dexterity to spin it efficiently with one finger, or it requires the user to realign her or his hands with the handles at every turn. In addition, a thief can assemble the bicycle using the built-in wrenches and flee upon it.

Aftermarket manufacturers have improved on the original design by elongating one arm of the “V” to engage the leaf holding the bolt, preventing its rotation. One manufacturer has instead engaged the steel leaf by inserting magnets into either end of one side of the clamp plate. This approach is unnecessarily costly to produce and has the disadvantage of collecting ferrous debris that might compromise the solidity of the joint.

Some upgrade kits provide springs positioned around the bolt between the clamp plate and the bolt-bearing leaf to urge them apart when the bolt is loosened. Springs may be long and narrow to fit in the groove around the bolt, or short and wide to fit outside of the hinges when closed. In either case, there is a tendency for the springs to be caught between the leaves when the bolt is tightened, causing damage to the spring and preventing a safe, secure joint.

Some kits provide screws that can be screwed into the end of the bolts, making them self-limiting, and so minimizing turning time and loss or damage to bolts, but may not provide the optimum range for every clamp.

SUMMARY

A clamp with an eyelet to position and protect a retraction spring, a counter-bore in the V-plate to accommodate the spring, and a finger loop to position the user's finger during operation. In some aspects the clamp may have a removable bolt-tightening handle, the release of which enables the handle to be removed to avoid damage and to prevent theft. The hole in the clamp plate is counter-bored on the “V” side to accommodate a spring, which surrounds the bolt. The bolt is inserted into a flanged tube, or eyelet, with the flange between the tube and the spring—that is, the tube fits into the grooves between hinge leaves and the bolt, preventing the spring from entering that space and getting caught. This spring, with its diameter unconstrained by the hinges, may be thicker and more durable than current springs. It may also exert more pressure on the clamp plate, urging it away from the hinge when released and also preventing it from turning. The tube of the eyelet, constrained by the bolt, keeps the eyelet flange from tilting. The eyelet flange, constrained by the passive hinge leaf, keeps the spring out of the way of the moving hinge leaf. Additionally, the design provides for easy removal and repositioning of the handle. The handle may easily be removed from the bolt without having to remove the locknut and bolt and having to readjust the locknut upon reinstallation.

A hinge clamp with a retained clamp plate that retains the position of the clamp plate near the handle when the hinge clamp is loosened. The clamp may be retained with a retention clip that resides in an annular groove along the bolt. The retained clamp plate moves to a position clear of the pivoting hinge plates as the bolt is unscrewed.

DRAWINGS

FIG. 1 is an exploded view of a hinge clamp in the open position according to some embodiments of the present invention.

FIG. 2 is a cross-sectional view of the side of the hinge when unlocked according to some embodiments of the present invention.

FIG. 3 is a cross-sectional view of the side of the hinge when locked according to some embodiments of the present invention.

FIG. 4 shows the handle about to be pressed onto the head of the bolt according to some embodiments of the present invention.

FIG. 5 shows the handle with its grooves pressed just past the head of the bolt according to some embodiments of the present invention.

FIG. 6 shows the handle rotated 30° around the head of the bolt according to some embodiments of the present invention.

FIG. 7 shows the handle withdrawn so as to capture the bolt head in the blind grooves according to some embodiments of the present invention.

FIG. 8 shows the first alternative handle in operating position according to some embodiments of the present invention.

FIG. 9 shows the first alternative handle being removed according to some embodiments of the present invention.

FIG. 10 shows the second alternative handle in operating position according to some embodiments of the present invention.

FIG. 11 is an exploded view of a hinge assembly with a retained clamp plate according to some embodiments of the present invention.

FIG. 12 is a cross-sectional view of a hinge assembly in a partially open position according to some embodiments of the present invention.

FIG. 13 is a cross-sectional view of a hinge assembly in a closed position according to some embodiments of the present invention.

FIG. 14A-D are views of a clamp plate according to some embodiments of the present invention.

DETAILED DESCRIPTION

In some embodiments of the present invention, as seen in FIG. 1, a clamp assembly is adapted to clamp in place a hinge assembly. The hinge assembly may have a passive hinge flange or leaf 110, having a passive bored lobe or barrel 110 c, a passive leaf chamfer 110 a which is parallel to the barrel, a threaded bolt barrel 110 b having a bore perpendicular to the passive bore, an active hinge leaf 112 having an active bored barrel or barrels 112 b, 112 c and an active leaf chamfer 112 a parallel to the bore. The aforementioned hinge leaves are aligned on their bores such that they are held together by a hinge pin 114 and the chamfers mirror each other.

A clamp assembly may have a bolt 116 having a threaded shaft 116 a and a bolt head 116 b. The bolt head 116 b is pressed into a socket 118 c in a handle 118, with the bolt and handle forming a “T” shape. At one end of the handle is finger loop 118 a with its axis parallel to that of the threaded shaft. In some aspects, the finger loop 118 a is a depression in the handle adapted to receive a user's finger such that the user may rotate the handle by inserting a finger into the finger loop 118 a, moving that finger in a rotary fashion, thereby rotating the handle, and tightening or loosening the bolt. At the end of the handle opposite the finger loop is a flattened thumb pad 118 b. In some aspects, the user may insert a finger into the finger loop, and also apply pressure with the thumb at the thumb pad, allowing the user to forcefully move the handle, such as when the user is wedging the clamp plate over the hinge leaves. An inner washer 120 is inserted between the threaded shaft of the bolt and the sides of the socket. An outer washer 122 is slid over the bolt, seating against the inner washer. A clamp plate 124 is slid over the bolt so that the spring bore 124 a faces away from the bolt head. A clamp spring 126 is slid over the bolt and inserted into the spring bore 124 a. An eyelet 128 is slid over the threaded shaft so that the eyelet flange 128 b rests against the spring and the eyelet skirt 128 a is positioned by the threaded shaft and keeps the eyelet flange perpendicular to the axis of the bolt.

The bolt 116 is threaded into the bolt barrel 110 b, and the active hinge leaf 112 is rotated until it rests against the passive hinge leaf 110 in order to allow for clamping of the hinge assembly.

A shorter ridge extension 124 b and a longer ridge extension 124 c parallel each other, extending from the clamp plate on either side of the spring bore. As the bolt is tightened, the clamp plate may be rotated just until the longer ridge extension is constrained by the passive hinge leaf. At this point, a locknut 130 can be screwed onto the bolt 116 until it contacts the back of the bolt barrel 110 b.

Continued tightening of the bolt will wedge the hinge leaves in between the ridge extensions 124 b, 124 c of the clamp plate 124 to create a solidly clamped hinge assembly. The inner faces of the ridge extensions 124 b, 124 c of the clamp plate have inclined surfaces 124 d, 124 e that mate with the chamfers on the hinge leaves. The ridges also have grip reliefs 124 f, 124 g (124 g is barely visible opposite 124 f) to ensure that clamping pressure is applied more to the extremities of the leaves for maximum stiffness.

The locknut 130 may be a standard Nylon-insert locknut. Other types of locknut may be used, including those that are deformed or swaged so as to hold tightly to their precise position on the bolt.

The bolt 116 may have a head in a form including, but not limited to, a hex head, a five-sided head, a square head, a triangular head, or a “Torx” type head comprising curved surfaces. FIG. 4 shows an embodiment featuring a bolt having a hex head.

In some aspects, the handle 118 is adapted to be able to be removed from the bolt 116 over the head 116 b of the bolt by rotation of the handle 118 relative to the head of the bolt 116. This allows for separate storage of the handle 118, but also allows for removal of the handle which makes it much harder to quickly clamp the hinge assembly. For example, a user may want to take the handle away from the folded bicycle to reduce the ease with which a potential thief may be able to assemble the folded bicycle and ride off. The handle 118 has a socket 118 c, which, in the case of a hex head, the top resembles a 12-point wrench socket. The underside of this socket opening 118 c resembles a six-pointed wrench socket with grooves parallel to its axis. A first plurality of these are through grooves 118 d, alternating with a second plurality of blind grooves 118 e blocked by landings 118 f to constrain the lower face of the bolt head 116 c so as to prevent the handle from falling off. A handle with these alternating through and blind grooves is adapted to allow the handle to be slid over the head of the bolt from underneath, when the through grooves are aligned with the points of the head of the bolt. Also, the handle may slide over the bolt head and slightly down the bolt shaft. Then the user may rotate the handle slightly such that the points of the bolt head engage upon the blind grooves. As the bolt is tightened further, washer 122 resists the advance of the handle 118 as the points of the bolt head put pressure upon the bottoms of the blind grooves in the handle, trapping the handle under the bolt head as part of the clamped assembly.

FIG. 2 shows a configuration of the hinge clamp with the bolt extended and the active leaf free to move between the fully open and closed positions. To unfold the bicycle or other structure from a compact, folded configuration in preparation for use: Starting with the hinge open, as it would be on a bicycle in a folded position, the user would rotate active hinge leaf 112 on hinge pin 114 against passive hinge leaf 110. The user may then place a finger in the finger loop 118 a of the handle 118. The user may then rotate the handle clockwise, driving a right-hand threaded bolt 116 against the inner washer 120 and the outer washer 122, and the clamp plate 124 against the clamp spring 126, which is held clear of the hinge leaves by a spring retainer 128, which may be an eyelet. The higher ridge extension 124 c on the clamp plate positioned against the passive chamfer prevents the clamp plate from rotating out of alignment with the passive hinge leaf, which might otherwise impede the process. Further rotation of the handle brings the inclined plate surfaces 124 d, 124 e to engage the passive and active leaf surfaces 110 a, 112 a, drawing them snugly together. By applying a thumb to thumb pad 118 b, and forefinger to finger loop 118 a, increased pressure may be applied to turn the bolt 116 in the clockwise direction, drawing the clamp plate tightly against hinge leaves, thereby creating a stiff and solidly clamped hinge assembly.

FIG. 3 shows the leaves pressed together and the bolt fully tightened, clamping the hinge leaves together to form a solid structure, with the spring held out by the eyelet flange and the bolt surrounded by the eyelet in part.

To fold: By applying a thumb to the thumb pad and a forefinger to the finger loop, the operator turns the handle counter-clockwise to relieve the tension holding the hinge leaves together.

Once loose, the handle can be spun counter-clockwise by operator's finger being inserted into the finger loop. As the bolt is retracted, the clamp spring 126 urges the clamp plate away from hinge leaves until the lock nut, semi-permanently affixed to the bolt, contacts the bolt barrel, preventing the bolt from further travel. At this point, the longer ridge extension is still constrained by its position against the passive leaf chamfer, but the active hinge leaf clears the lower ridge extension, allowing the structure to be folded.

A method to remove or reposition the handle on the hex head bolt shown in FIGS. 4 through 7. A user may choose to mark the bolt head so as to be able to return the handle to the same position or relocate it to another chosen position vis-à-vis the cue 118 g when reinstalling it. Turn handle all the way counter-clockwise to withdraw the bolt from the hinge. Push handle towards hinge as far as possible, then turn handle another one-twelfth turn (30°), and withdraw it. Reverse the process to reinstall the handle.

In an example using a six-sided bolt, six points of the twelve-point socket cut clear through the handle. This plurality of through grooves has the same shape as the outline of the bolt head, and they allow the handle to be pressed down over the bolt head. Turning the handle 30° aligns the head with a second plurality of points or grooves, which are blind grooves, which come in from the top, but stop short at landings congruent with the top surface of the inner washer, capturing the bolt head when it is tightened. The handle 118 is adapted to slide off over the head of the bolt 116 in a first rotary configuration relative to the bolt, and to be retained under the head of the bolt 116 in a second rotary configuration relative to the bolt.

In this configuration, the installed handle can be pushed towards the end of the bolt away from the head. It can then be rotated to the next set of grooves and slid off for safekeeping, or rotated to a more convenient position and retightened. When handles are removed, they eliminate projections that can snag when the folded bike is being carried by hand or transported in compartments of vehicles. Removing the handles also may prevent a thief from riding the bicycle away unless she or he was supplied with a wrench. The handles are more delicate than the bolt heads, so removing them and carrying them separately would protect them from damage and allow them to be easily replaced. This configuration also simplifies repositioning the handles for convenience or for a neater appearance.

FIG. 4 shows an orientation cue 118 g emphasizing alignment along the blind grooves. This provides a visual cue to the operator, who would align a chosen face of the bolt head with that flat to secure it in a preferred position.

The handle described, while bearing a finger loop and thumb pad, may be affixed to the bolt in a permanent or semi-permanent manner. It may be removable or it may not be removable without first removing all other parts from the bolt. In these cases, convenience might be sacrificed in the interest of simplicity and durability.

In additional embodiments allowing the handle to be removed without removing the bolt, the two may be held together by other means: The handle may be applied from the top or bottom. It may be pressed on, it may be held on by one or more clips, screws, pins, magnets, snap rings, or other means.

In some embodiments of the present invention, as seen in FIGS. 8 and 9, the handle for clip 210 is held in place on a bolt 200, which may be a square-headed bolt, by means of a handle clip 212 which pivots on a clip pin 214 and is urged into position by a clip spring 216.

In this configuration, the operator releases the handle by pressing the lever of the clip against the body of the handle. This withdraws the latch from the base of the bolt head, allowing it to rotate out of its socket and be withdrawn. To apply the handle for clip, the operator first hooks the handle landing 210 a onto a lower edge of the bolt head 116 c. She or he then pivots the finger hole end of the handle about the landing until the latch of the clip, urged by the spring, snaps into place. Again, this embodiment allows for the handle to be removed from the bolt over the head of the bolt, but also allows the handle to be captured below the head of the bolt in the clamped position.

In some embodiments of the present invention, as seen in FIG. 10, the handle is slipped onto the bolt from outside and held onto the bolt head by a captive screw 314, which is screwed into a threaded bore 312 a in the bolt head. The screw is retained by threads 310 a in the handle, but is allowed to turn free of the handle by means of an annular groove or neck 314 a separating the threaded portion of the captive screw from the screw head. The captive screw may be captured by a circular clip or other means. The screw may be replaced by a snap fitting or other fastening means that allow relatively weak resistance to telescoping, while maintaining firm transmission of rotary force. The screw could have any form of head, including, but not limited to a wing bolt, thumbscrew or hex head. To release the handle in this configuration, the captive screw is unscrewed from the bolt head, driven by a coin or screwdriver if necessary. Once the screw is free of the bolt head, and before it is unscrewed from the handle, the handle may be removed.

In some embodiments of the present invention, as seen in FIG. 11, and in cross-section in FIGS. 12 and 13, a dual retention clamp assembly 400 with a retained handle is adapted to clamp in place a hinge assembly. The hinge assembly may have a passive hinge flange or leaf 410, having a passive hinge flange bored lobe or barrel 410 c, a passive leaf hinge bore 410 a which is perpendicular to the barrel 410 c, a threaded bolt barrel 410 b having a bore parallel to the passive hinge flange barrel 410 c, and a passive leaf chamfer 410 d. The hinge assembly may also have an active hinge leaf 412 having an active leaf hinge bored barrel or barrels 412 b, 412 c and an active leaf chamfer 412 a parallel to the hinge bored barrel or barrels. The aforementioned hinge leaves are aligned on their hinge bores and are held together by a hinge pin 414.

A dual retention clamp assembly 400 with a retained clamp plate may have a bolt 416 having a threaded shaft 416 a and a bolt head 416 d. The bolt 416 may also have an inboard groove 416 c and an outboard groove 416 b. The inboard groove 416 c is adapted to receive a clip 431 that will retain the clamp plate 424 with the handle 428 and will be restrained by the bolt head 416 d. The outboard groove 416 b may be adapted to retain a circlip 434 or device adapted to reside in the groove 416 b to provide an axial stop along the barrel of the bolt 416. As described below, as the handle is turned to unscrew the bolt, which loosens the clamp, the axial stop may stop the bolts loosening so that the clamp plate 424 is at a specific point wherein the bolt has been loosened enough so that the active hinge leaf 412 may be pivoted away from the passive hinge leaf 410, allowing for the opening of the hinge. At the same time, the clip has limited the distance that the bolt may unscrew so that the longer, lower, portion 424 a of the clamp plate 424 is restrained from pivoting much by the passive leaf 410 in the region of the passive leaf chamfer 410 d. This dual retention system, as described further below, retains the clamp plate 424 against the handle 428, such that the clamp plate travels away from the hinge leaves with the handle as the clamp is loosened, and also constrains the travel of the bolt such that the lower portion 424 a of the clamp plate is constrained from over-rotation, retaining the clamp plate in the proper location for subsequent re-clamping of the clamping system without alignment by the user.

The bolt head 416 d is pressed into a socket 428 a in a handle 428, with the bolt and handle forming a “T” shape. At one end of the handle is finger loop with its axis parallel to that of the threaded shaft, or a depression similarly useful for aiding the user in rotating the handle. At the end of the handle opposite the finger loop is a flattened pad. In some aspects, the user may insert a finger into the finger loop, and also apply pressure with the thumb at the other side of the handle, allowing the user to forcefully move the handle, such as when the user is wedging the clamp plate over the hinge leaves. A spacer 435 is adapted to reside under the head of the bolt, and to be thick enough to take the axial load from the underside of the bolt head instead of that axial load loading the handle 428. The handle is used to rotate the bolt head, but does not form part of the axial load path. A washer 436 may be inserted between the spacer 435 and the clamp plate 424, and may keep the clamp plate from abrading the handle. A second spacer 432 may be used to fine tune the configuration of the portion of the assembly between the clip 431 and the handle 428. A counterbore 424 h in the clamp plate 424 is adapted to receive the second spacer 432.

As seen in cross-section in FIG. 12 with the hinge in a partially opened position, the clamp plate 424 is retained against the handle 428 and the bolt head 416 d. A clip ring 431 resides in the inboard groove 416 c, axially constraining the clamp plate 424. A washer 432 may reside between the clip ring 431 and the clamp plate 424. A washer 436 and a spacer 435 may space and align the handle 428 relative to the clamp plate 424.

At the outboard end of the bolt 416, a clip plate 434 in a groove 416 b and a washer 433 work to prevent the bolt 416 from further axial motion as the bolt is unwound to allow for the opening of the hinge assembly. The clamp plate 424 has a lower portion 424 a and an upper portion 424 c adapted to clamp down on the passive hinge leaf 410 and the active hinge leaf 412 when the hinge is in the clamped, closed, position. The lower portion 424 a of the clamp plate extends farther than the upper portion 424 c, such that when the bolt 416 is loosened until the washer 433 and the clip plate 434 constrain further travel, the active leaf 412 is able to clear the upper portion 424 c and the clamp assembly may be fully opened. At the same time, the lower portion 424 a of the clamp plate 424 is still constrained under the extending portion of the passive leaf 410. This constraining aspect of the lower portion 424 a prevents the clamp plate from rotating to a position that would preclude re-clamping without manual realignment.

In use, the clamp assembly with a retained clamp plate allows for the opening of the hinge assembly by unscrewing the bolt by using the handle 428. As the handle 428 is unscrewed, the bolt travels outbound from the hinge assembly. As the bolt travels outbound, the clamp plate handle also travels outbound with the bolt and handle. In such an arrangement no spring is needed to help the clamp plate stay clear of the hinge flanges, as it has traveled outbound with the handle and bolt head. As the bolt travels further outbound, it is constrained from overtravel by the clip plate 434. Thus, there are two constraints restraining the system as it is loosened; a first restraint that keeps the clamp plate against the handle, and a second restraint that prevents travel of the bolt such that the lower portion of the clamp plate stays in a correct rotational position for re-clamping of the clamp without manual realignment.

FIG. 13 illustrates in cross-section the hinge clamp assembly with a retained clamp plate in a closed position. As seen in a cross-section down the center axis, there are contact regions 424 d and 424 e where contact will occur for clamping of the clamp plate to the active and passive leaves. FIGS. 14 A-D illustrate the clamp plate 424. As seen in FIG. 14D, the regions 424 e and 424 d present a recessed area due to the cutout area for the bolt and washers, and contact may not occur in these regions. The side regions 424 f and 424 g present planar regions where contact with the hinge leaves occurs to provide clamping force when the clamp is closed. A counterbore 424 h in the clamp plate 424 is adapted to receive the second spacer 432. As seen in FIG. 14A, a groove cut 424 b in the lower portion 424 a of the clamp plate 424 allows for clearance between the extended lower portion and protruding portions of the passive leaf 412.

As evident from the above description, a wide variety of embodiments may be configured from the description given herein and additional advantages and modifications will readily occur to those skilled in the art. The invention in its broader aspects is, therefore, not limited to the specific details and illustrative examples shown and described. Accordingly, departures from such details may be made without departing from the spirit or scope of the applicant's general invention. 

What is claimed is:
 1. A clamp assembly adapted to clamp a hinge assembly of a folding bicycle, said clamp assembly comprising: a first hinge flange; a second hinge flange, said second hinge flange pivotally connected to said first hinge flange about a pivot axis, said second hinge flange comprising a threaded bore; a bolt barrel formed on an end of either the first flange or the second flange, said bolt barrel extending in a direction transverse to said pivot axis; a clamp plate, said clamp plate comprising: a central plate portion; an upper ridge extension extending from an upper area of said central plate portion adapted to clamp onto a protruding portion of said first hinge flange; a lower ridge extension extending from a lower area of said central plate portion adapted to clamp onto a protruding portion of said second hinge flange; and a hole through said central plate portion, wherein said clamp plate resides on said bolt with said bolt traversing through said hole in said clamp plate a bolt, wherein said bolt comprises: a first end and a second end; a bolt head on a first end; a bolt shaft, said bolt shaft passing through said hole in said clamp plate and engaging within said bolt barrel; a threaded bolt shaft portion adapted to thread into said bolt barrel; and a first groove in said bolt near a second end of said bolt that has passed through said bolt barrel, and a first retainer residing in said first groove, wherein when the first and second flanges are pivoted to a locked position in which the first and second flanges are axially aligned, turning said bolt moves said clamp plate toward said pivot axis, such that the upper and lower ridge extensions engage outer portions of said first and second flanges, thereby locking said first and second flanges against pivoting relative to each other.
 2. The clamp assembly of claim 1 further comprising a handle coupled to said bolt, said handle comprising a first end and a second end.
 3. The clamp assembly of claim 2 wherein said handle further comprises a thumb pad on said first end of said handle.
 4. The clamp assembly of claim 3 wherein said handle further comprises a finger loop on said second end of said handle.
 5. The clamp assembly of claim 4 wherein said bolt further comprises a second groove in said bolt near a first end of said bolt, said second groove adapted to receive a second retainer, and wherein said clamp assembly further comprises a second retainer residing in said second groove.
 6. The clamp assembly of claim 5 wherein said second flange comprises said bolt barrel, and wherein said second flange is longer than said first flange.
 7. The clamp assembly of claim 6 wherein said first retainer is located along said bolt such that said bolt is constrained from further unscrewing at a position wherein said clamp plate is constrained from rotation by said second flange interfering with said lower ridge extension.
 8. The clamp assembly of claim 2 wherein said handle further comprises a finger loop on said second end of said handle.
 9. The clamp plate assembly of claim 8 wherein said clamp plate further comprises a PTFE impregnated anodized finish.
 10. The clamp assembly of claim 2 wherein said bolt further comprises a second groove in said bolt near a first end of said bolt, said second groove adapted to receive a second retainer, and wherein said clamp assembly further comprises a second retainer residing in said second groove.
 11. The clamp assembly of claim 10 wherein said second flange comprises said bolt barrel, and wherein said lower ridge extension is longer than said upper ridge extension.
 12. The clamp assembly of claim 11 wherein said first retainer is located along said bolt such that said bolt is constrained from further unscrewing at a position wherein said clamp plate is constrained from rotation by said second flange interfering with said lower ridge extension.
 13. The clamp plate assembly of claim 2 wherein said clamp plate further comprises a PTFE impregnated anodized finish.
 14. A clamp plate assembly, said clamp plate assembly comprising: a central plate portion; an upper ridge extension extending from an upper area of said central plate; a lower ridge extension extending from a lower area of said central plate portion; and a hole through said central plate portion; a bolt, wherein said bolt comprises: a first end and a second end; a bolt head on a first end; a bolt shaft; a threaded bolt shaft portion; a first groove in said bolt shaft adapted to receive a first retainer; a second groove in said bolt near a second end of said bolt that has passed through said bolt barrel, said second groove adapted to receive a second retainer; a handle coupled to said bolt head, said handle comprising a first end and a second end, said handle adapted to turn said bolt, and a first retainer, said first retainer residing in said first groove, said first retainer retaining said clamp plate at said first end of said bolt; and a second retainer residing is said second groove.
 15. The clamp plate assembly of claim 14 wherein said lower ridge extension extends farther from said central plate than said upper ridge extension, and wherein said lower ridge extension comprises a groove along the length of its upper surface.
 16. The clamp plate assembly of claim 15 wherein said handle further comprises a finger loop on said second end of said handle.
 17. The clamp plate assembly of claim 15 wherein said clamp plate further comprises a PTFE impregnated anodized finish.
 18. The clamp plate assembly of claim 14 wherein said handle further comprises a finger loop on said second end of said handle.
 19. The clamp plate assembly of claim 14 wherein said clamp plate further comprises a PTFE impregnated anodized finish. 